generate.data: Simulate Data from Mixed-Effects Models
In nlmm: Generalized Laplace Mixed-Effects Models

generate.data

R Documentation

Simulate Data from Mixed-Effects Models

Description

This function generates data from a 2-level hierarchical design.

Usage

generate.data(R, n, M, sigma_1 = NULL, sigma_2 = NULL,
	shape_1 = NULL, shape_2 = NULL, dist.u, dist.e,
	beta, gamma, fixed = FALSE, seed = round(runif(1,1,1000)))

Arguments

`R`	number of replications.
`n`	number of observations within cluster.
`M`	number of clusters.
`sigma_1`	scale parameter for the random effects.
`sigma_2`	scale parameter for the errors.
`shape_1`	shape parameter for the random effects.
`shape_2`	shape parameter for the errors.
`dist.u`	distribution of the random effects.
`dist.e`	distribution of the errors.
`beta`	vector of coefficients for fixed effects.
`gamma`	vector of coefficients for heteroscedasticity.
`fixed`	logical flag. See details.
`seed`	seed for random number generation.

Details

This function generates data as in the simulation study by Geraci and Farcomeni (2020). The data-generating model is

y[ij] = \beta[0] + \beta[1]x[ij] + \beta[2]z[ij] + u[i] + v[i]x[ij] + (\gamma[0] + \gamma[1]x[ij])e[ij]

where (u[i],v[i]) follows a distribution with scale sigma_1 and shape shape_1, and e follows a distribution with scale sigma_2 and shape shape_2.

The scale parameter sigma_1 must be a 1 by 1 or a 2 by 2 matrix. In the former case, the model will include only random intercepts. In the latter case, then both random intercepts and slopes will be included. Currently, no more than 2 random effects can be specified. The scale parameter sigma_2 must be a matrix n by n.

The options for dist.u and dist.e are: multivariate normal ("norm") (rmvnorm), multivariate symmetric Laplace ("laplace") (rmal), multivariate symmetric generalized Laplace ("genlaplace") rmgl, and multivariate Student's t ("t") (rmvt).

The shape parameter specifies the degrees of freedom for Student's t and chi-squared, and the kurtosis of the generalized Laplace.

The values x[ij] are generated as x[ij] = \delta[i] + \zeta[ij], where \delta[i] and \zeta[ij] are independent standard normal. If the argument fixed = TRUE, then x[ij] = j. The values z[ij] are generated from Bernoullis with probability 0.5.

Value

nlmm returns an object of class nlmm.

The function summary is used to obtain and print a summary of the results.

An object of class nlmm is a list containing the following components:

`Y`	a matrix `R x N`, where `N = n x M`, with responses
`X`	an array `N x 3 x R` with fixed design matrix
`group`	vector of length `N` with cluster labels
`u`	an array `M x 2 x R` with random effects
`e`	a matrix `R x N` with errors

Author(s)

Marco Geraci

References

Geraci, M. and Farcomeni A. (2020). A family of linear mixed-effects models using the generalized Laplace distribution. Statistical Methods in Medical Research, 29(9), 2665-2682.

Examples


# Simulate 10 replications from a homoscedastic normal mixed model.
generate.data(R = 10, n = 3, M = 5, sigma_1 = diag(2), sigma_2 = diag(3),
shape_1 = NULL, shape_2 = NULL, dist.u = "norm", dist.e = "norm",
beta = c(1,2,1), gamma = c(1,0))

# Simulate 10 replications from a generalized Laplace. Note: the shape
# parameter that is passed to rmgl corresponds to the reciprocal of the
# parameter alpha in Geraci and Farcomeni (2020)
generate.data(R = 10, n = 3, M = 5, sigma_1 = diag(2), sigma_2 = diag(3),
shape_1 = 1/0.5, shape_2 = 1/0.5, dist.u = "genlaplace", dist.e = "genlaplace",
beta = c(1,2,1), gamma = c(1,0))

nlmm documentation built on Nov. 24, 2023, 5:11 p.m.